KR101961231B1 - Image display device and method - Google Patents

Abstract

An object of the present invention is to improve the color reproducibility of the dark area by improving the contrast ratio and correcting the color balance using two LCD panels.
Side LCD panel 35 and the rear-side LCD panel 36, and the backlight is transmitted in the order of the rear-side LCD panel 36 and the front-side LCD panel 35, An RGB image signal after color balance correction is generated from an RGB image signal based on an input RGB image signal and includes an RGB grayscale conversion circuit 332 and a color balance controller 333, A first controller (33) for supplying the RGB image signals after the color balance correction to the LCD panel (35); and a controller (33) for performing signal processing on the RGB image signals based on the input RGB image signals, And a second controller (34) for generating a gray image signal and supplying the gray image signal after the signal processing to the rear side LCD panel (36), wherein the RGB gradation conversion circuit (332) First lookup tables 3321, 3322, and 3323 for performing first tone conversion on image signals and second lookup tables 3324, 3325, and 3326 for performing second tone conversion on RGB image signals, And the first look-up tables 3321, 3322, and 3323 are applied to the RGB image signals based on the input RGB image signals to perform the first tone conversion, And the second lookup tables 3324, 3325, and 3326 are applied to the RGB image signals based on the input RGB image signals to perform the second tone conversion, And the color balance controller 333 generates the color balance correction image signals after the second gradation conversion for each of the R, G, The RGB individual correction coefficient is calculated by further multiplying an adjustment function having a range from 0 to 1 with respect to the luminance ratio obtained by dividing the luminance signal by the phase signal and further multiplying the RGB image signal after the first gradation conversion by the RGB individual correction coefficient, An image display apparatus for generating an RGB image signal after color balance correction is provided.

Description

[0001] Image display device and method [0002]

The present invention relates to an image display apparatus and an image display method for performing color balance correction together with a contrast ratio improvement.

In the conventional image display apparatus using one LCD panel, the panel driver corrects the input image by the line gamma, thereby realizing the gradation linear characteristic in the naked eye.

However, in practice, since the backlight illumination is transmitted through the liquid crystal panel, the so-called black floating phenomenon occurs, in which the gray level characteristic of the black region is poor and the luminance is observed in the bright direction compared with the ideal luminance do.

This phenomenon occurs when the LCD panel is not completely shielded from light when the dark area is displayed on the LCD panel, and the backlight illuminates. A contrast ratio of about 10,000: 1 is achieved in a conventional CRT, and a contrast ratio of about 1,000,000: 1 is realized in an organic EL panel. However, according to the present invention, in the conventional image display apparatus using one LCD panel, the contrast ratio is only about 1,500: 1.

Therefore, in order to improve the contrast ratio of an image display apparatus using such a single LCD, an image display apparatus using two LCDs has been proposed (see, for example, Patent Documents 1 and 2). Any of the image display apparatuses is configured to use two LCDs, the rear LCD to adjust the transmission amount of the backlight, and the front LCD to perform RGB display, thereby improving the contrast ratio.

Patent Document 1: JP-A-5-88197 Patent Document 2: International Publication No. 2007/108183

However, the prior art has the following problems.

As described above, in the image display apparatus using one LCD panel, there is a problem that the contrast ratio can only be realized at about 1,500: 1. Furthermore, with one LCD, it is a big problem that the image can not be reproduced faithfully due to the deterioration of the color reproducibility and the quality of black in the dark image.

On the other hand, an image display device using two LCD panels as in Patent Documents 1 and 2 has an effect of improving contrast and preventing black-floating. However, there is no mention of improvement in color reproducibility.

16 is a diagram for explaining a problem of the conventional image display apparatus 100 using two LCD panels. The LCD panel on the rear side backlight 103 side is referred to as an LV panel 102 and the front side LCD panel on the side closer to the viewer of the image is referred to as an RGB panel 101. [

As shown in Fig. 16, the RGB panel 101 is composed of R, G, and B sub-pixels. On the other hand, the LV panel 102 combines the R, G, and B sub-pixels into one pixel. That is, one pixel of the LV panel 102 is common to one pixel of the sub-pixels of the RGB panel 101 and corresponds to 1: 1.

Therefore, in the image obtained by passing through one pixel of the LV panel 102 and transmitted through each sub-pixel of the RGB panel 101, luminance adjustment is performed by combining RGB. Therefore, the following first and second problems occur.

Problem 1: Whitening of color due to light spots occurs in the dark part.

For example, in the case of pure color that makes any one of RGB shine, there is a problem that when R is glowed and GB is not glowed, R is whitened (it becomes like white) with GB light spots.

The second problem: color balance is broken.

For example, in the case of mixed color that makes all of R, G, and B shine, the LV value is common to all subpixels, not the LV value, that is, the LV value of the LV pixel corresponding to the original luminance value of each RGB. Therefore, there is a problem in that the RGB luminance value after transmission as a product of the transmittance of each of the LV panel and the RGB panel is different from the original RGB, so that the color balance is discolored and discolored.

An object of the present invention is to provide an image display apparatus and an image display method capable of improving the color reproducibility of a dark region by correcting the color balance while improving the contrast ratio by using two LCD panels .

The image display device according to the present invention is constituted by superposing two front-side LCD panels and a rear-side LCD panel, and the backlight is transmitted in the order of the rear-side LCD panel and the front- An image display apparatus includes an RGB gradation conversion circuit and a color balance controller to generate an RGB image signal after color balance correction from an RGB image signal based on an input RGB image signal, A first controller for supplying a subsequent RGB image signal and a second controller for generating a gray image signal after the signal processing by performing signal processing on the RGB image signal based on the input RGB image signal, And a second controller for supplying the back side LCD panel with RGB gradation conversion circuits, And a second lookup table for performing a second gradation conversion on an RGB image signal are separately stored for each color of R, G, and B, and the input RGB image signal The first look-up table is applied to the RGB image signal based on the input image signal to generate the RGB image signal after the first gradation conversion, and on the other hand, the RGB image signal based on the input RGB image signal Wherein the color balance controller generates the color balance correction image signal after performing the second gradation conversion by applying the second lookup table to the second lookup table, The luminance image signal obtained by dividing each of the correction image signals by the gray image signal after the signal processing, The RGB individual image correction coefficient is calculated by further multiplying the adjustment function of 0 to 1, and the RGB image signal after the color balance correction is generated by multiplying the RGB image signal after the first gradation conversion by the RGB individual correction coefficient.

Further, the image display method according to the present invention is constituted by superposing two front-side LCD panels and a rear-side LCD panel, and the backlight is transmitted through the rear-side LCD panel and the front-side LCD panel in this order, An image display method executed by an image display apparatus, the method comprising the steps of: performing RGB gradation conversion processing and color balance correction processing on an RGB image signal based on an input RGB image signal to generate an RGB image signal after color balance correction; Processing the RGB image signal based on the RGB image signal to generate a gray image signal after signal processing to supply the RGB image signal after the color balance correction to the front side LCD panel, The gray image signal after the signal processing is supplied to the panel, and the RGB gradation conversion processing A first lookup table for performing first tone conversion on an RGB image signal individually stored for each color of RGB and a second lookup table for performing a second tone conversion on RGB image signals, The first look-up table is applied to the RGB image signal based on the input RGB image signal to generate the RGB image signal after the first tone conversion by performing the first tone conversion, and on the basis of the input RGB image signal And the second look-up table is applied to one RGB image signal to perform the second tone conversion, thereby generating a color balance correction image signal after the second tone conversion, and in the color balance correction processing, Each of the color balance correction image signals after the 2-tone conversion is obtained by dividing the image signals after the signal processing by the gray image signals Calculates an RGB individual correction coefficient by further multiplying an adjustment function having a range from 0 to 1 with respect to a luminance ratio, and multiplies the RGB individual correction coefficient with respect to the RGB image signal after the first tone conversion.

According to the present invention, there is provided a configuration capable of generating an RGB image in which the color balance is corrected in consideration of the grayscale conversion result of the LV image while performing grayscale conversion for the RGB image. As a result, it is possible to obtain an image display apparatus and an image display method which can improve the color reproducibility particularly in the dark region by correcting the color balance while improving the contrast ratio by using two LCD panels.

1 is a signal processing block diagram of an image display apparatus according to Embodiment 1 of the present invention.
2 is a more detailed signal processing block diagram of the bit expansion circuit, the RGB controller, and the LV controller included in the image display apparatus according to the first embodiment.
3 is an explanatory diagram of bit expansion processing by the bit expansion circuit of the first embodiment.
4 is a graph showing the gradation conversion characteristics of the LUT (R) of the first embodiment.
5 is a graph showing the gradation conversion characteristics of the LUT (W) in the first embodiment.
6 is a detailed configuration diagram of the edge hold circuit according to the first embodiment.
7 is a flowchart related to a local edge hold process by the edge hold circuit according to the first embodiment.
8 is a waveform chart showing the operation result of the local edge hold process performed by the edge hold circuit according to the first embodiment.
9 is an explanatory diagram for improving the color reproducibility of an arm portion by operation of the LUT and the color balance controller of the first embodiment.
Fig. 10 is an explanatory diagram of color balance adjustment in the dark area by the operation of the color balance controller of the first embodiment. Fig.
Fig. 11 is an explanatory view of correction coefficients in the color balance controller of the first embodiment. Fig.
12 is an explanatory diagram showing the experimental results of the first embodiment.
Fig. 13 is an explanatory diagram showing the experimental results of the first embodiment; Fig.
14 is a schematic cross-sectional view of a display module using two LCD panels according to the first embodiment.
15 is an explanatory diagram of an adjustment function of a modification of the present invention.
16 is a diagram for explaining a problem of a conventional image display apparatus using two LCD panels.

Best Mode for Carrying Out the Invention Hereinafter, preferred embodiments of the image display apparatus and the image display method of the present invention will be described with reference to the drawings.

The image display apparatus of Embodiment 1 is configured by superposing two front-side LCD panels and a rear-side LCD panel, and the backlight is transmitted through the rear-side LCD panel and the front-side LCD panel in this order, An RGB image signal after the color balance correction is generated from the RGB image signal based on the input RGB image signal and the RGB image signal after the color balance correction with respect to the front side LCD panel is generated by the RGB grayscale conversion circuit and the color balance controller, And a second controller for supplying a gray image signal after signal processing to the rear side LCD panel by performing signal processing on RGB image signals based on the input RGB image signals to generate gray image signals after signal processing, And a second controller, wherein the RGB gradation conversion circuit includes a first gradation conversion unit for performing first gradation conversion on the RGB image signals, Up table and a second lookup table for performing a second gradation conversion on an RGB image signal are separately stored for each color of R, G, and B. For an RGB image signal based on an input RGB image signal, a first look- To perform the first gradation conversion to generate the RGB image signal after the first gradation conversion and to apply the second lookup table to the RGB image signal based on the input RGB image signal to perform the second gradation conversion, The color balance controller generates an image signal for color balance correction after the 2-tone conversion, and the color balance controller calculates an average of the luminance ratio obtained by dividing each of the color balance correction image signals after the second gradation conversion generated separately for each RGB by the gray image signal after signal processing The adjustment function with the range from 0 to 1 is further multiplied to calculate the RGB individual correction coefficient, and the RGB An RGB image signal after the color balance correction is generated by multiplying the image signal by the RGB individual correction coefficient.

<Overall configuration>

First, the entire configuration will be described.

1 is a signal processing block diagram of an image display apparatus according to the first embodiment. The image display apparatus 10 of the first embodiment shown in Fig. 1 is constituted by including an image display apparatus main body 20 and an LCD module 30. Fig.

Here, the image display apparatus main body 20 includes an image processing engine 21. The LCD module 30 includes an interface 31, a bit expansion circuit 32, an RGB controller (first controller) 33, an LV (light valve) controller (second controller) 34, an RGB panel A front side LCD panel 35, and an LV panel (rear side LCD panel) 36.

The image processing engine 21 in the image display apparatus main body 20 generates an RGB image and transmits it to the LCD module 30. [ On the other hand, the I / F 31 in the LCD module 30 receives the RGB image generated by the image processing engine 21 and transmits it to the bit expansion circuit 32 as an input RGB image signal.

2 is a more detailed signal processing block diagram of the bit expanding circuit 32, the RGB controller 33 and the LV controller 34 included in the image display apparatus of the first embodiment.

The bit expansion circuit 32 performs bit extension processing on 12-bit images for each of the input 8-bit RGB image. The bit extension processing is to extend the bit length precisely in advance in order to prevent the bit precision from deteriorating in the subsequent processing. The bit expansion circuit 32 transmits the RGB image after bit expansion to the RGB controller 33 and the LV controller 34, respectively.

The bit expanding circuit 32 of the first embodiment expands the 8-bit data 50, that is, the 8-bit image signal to 12-bit data, for example, as shown in Fig. 3 (a) . In the case of quantizing an image signal originally analogue to 8 bits, a change in bit resolution or lower is rounded off. However, since the correlation between adjacent pixels is high, an image can be restored to some extent by introducing the following method.

Fig. 3 (b) is an explanatory diagram of a pixel to be processed, that is, a pixel of interest X5, and Fig. 3 (c) is an example of a bit extension processing sequence expressed in a program format. 3, the bit extending circuit 32 performs a bit expansion on the eight pixels (X1 to X4, X6 to X9) adjacent to the periphery of the target pixel X5 with respect to the variable dc initialized to 0 as shown in Fig. -1 when the luminance value of the pixel X5 is smaller than the luminance value of each adjacent pixel, and -1 when the luminance value of the pixel X5 is larger than the luminance value of each adjacent pixel.

Further, the bit extending circuit 32 adds 8 bits of the total value, that is, the value obtained by dividing dc by 8, to the pixel of interest X5 as a weight 51 of a fraction less than the decimal point, Extension is performed.

For example, when the luminance values of neighboring pixels are all large relative to the luminance value of the pixel X5, the luminance value of each pixel is rounded to 8 bits, The original value of the luminance value of the target pixel X5 is assumed to be a continuous concave shape and the original analog value of the luminance value of the target pixel X5 is estimated to be larger than the data rounded by 8 bits.

On the other hand, when the luminance values of the surrounding pixels are all small relative to the luminance value of the pixel X5, the waveform at the analog value, which is the original value before the luminance value of each pixel is rounded to 8 bits, becomes a continuous convex shape And the analog value which is the original value of the luminance value of the target pixel X5 is estimated to be smaller than the data rounded by 8 bits. Therefore, the bit expanding circuit 32 performs bit extension processing as shown in FIG. 3 on the basis of this basis.

As for the bit extension method, a method other than the method described here may be adopted.

Next, the rear end processing of the bit expanding circuit 32 will be described. 2, the RGB controller 33 includes a delay circuit 331, an RGB gradation conversion circuit 332 having six LUTs (look up tables 3321, 3322, 3323, 3324, 3325, and 3326) And a color balance controller 333.

On the other hand, the LV controller 34 includes a gray converter 341, an LV gradation conversion circuit 342 having one LUT 3421, a horizontal direction edge hold circuit 343, a vertical direction edge hold circuit 344, A pass filter 345, and a round processing unit 346.

The delay circuit 331 in the RGB controller 33 receives the RGB image (RGB image signal based on the input RGB image signal) after the bit expansion from the bit expansion circuit 32 and outputs the RGB image after the bit expansion To be properly delayed. Appropriately delayed &quot; is intended to compensate for processing delay caused by the gray converter 341, the horizontal edge hold circuit 343, the vertical edge hold circuit 344 and the LPF 345 in the LV controller 34 .

In the first embodiment, four kinds of LUTs, that is, the LUT (R) as the LUT for the subpixel (R), the LUT (G) as the LUT for the subpixel (G), the LUT LUT (W) which is a LUT for gray image is used. The RGB gradation conversion circuit 332 in the RGB controller 33 includes one LUT (R) 3321, LUT (G) 3322 and LUT (B) 3323 (first LUTs 3321, 3322 and 3323 ) And three LUTs (W) 3324, 3325, and 3326 (second LUTs 3324, 3325, and 3326). The LV gradation conversion circuit 342 in the LV controller 34 is provided with an LUT (W) 3421 (third LUT 3421).

The RGB gradation conversion circuit 332 in the RGB controller 33 performs the gradation conversion for the respective colors after the delay by using the first and second LUTs 3321, 3322, 3323, 3324, 3325, and 3326 G2 and B2 after the first gradation conversion and the color balance correction image signals L _R , L _G and L _B after the second gradation conversion are generated. The details of the gradation conversion processing performed by the RGB gradation conversion circuit 332 will be described later with reference to the description of the LV gradation conversion circuit 342 in the LV controller 34. [

On the other hand, the gray container 341 in the LV controller 34 receives the RGB image (RGB image signal based on the input RGB image signal) after bit expansion from the bit expanding circuit 32, and outputs the RGB A gray image having a maximum value among the three luminance values of R, G, and B as representative values for each pixel is converted into an image.

Generally, in the conversion to gray scale, luminance is often obtained by performing color matrix conversion using a multiplier and an adder. The gray converter 341 according to the first embodiment is configured such that the R, G, and B luminance values of each pixel are adjusted so that the color balance controller 333 in the RGB controller 33 can easily perform the RGB color balance correction. The maximum value is detected and outputted as a representative value, thereby simplifying the hardware.

Needless to say, it is needless to say that the color balance correction processing can be performed without any problem even when a typical matrix conversion is adopted.

Next, the LV gradation conversion circuit 342 in the LV controller 34 performs gradation conversion (third gradation conversion) using the third LUT 3421 for the gray image. Details of the tone conversion processing by the LV gradation conversion circuit 342 will be described below with reference to the description of the RGB tone conversion circuit 332 in the RGB controller 33. [

Further, the horizontal direction edge hold circuit 343 and the vertical direction edge hold circuit 344 in the LV controller 34 perform the viewing angle correction on the gray image after the gray level conversion. By applying the LPF 345 so that the brightness value after the adjustment becomes natural over the entire image, the change between the adjacent brightness values is slowed down so that the gray image B / W image).

The LV controller (second controller) 34 performs the above-described signal processing on RGB image signals based on the input RGB image signals, and generates gray image signals after signal processing.

The gray image after the signal processing is transmitted to the color balance controller 333 in the RGB controller. The gray image after the signal processing is displayed on the LV panel 36 after the brightness value is rounded to 8 bits by the round processing unit 346. [ Details of the viewing angle correcting process by the horizontal direction edge hold circuit 343 and the vertical edge hold circuit 344 will also be described later with reference to the drawings.

The color balance controller 333 in the RGB controller 33 receives the signals after the first and second gradation conversion by the RGB gradation conversion circuit 332 and the signals after the third gradation conversion by the LV gradation conversion circuit 342 And the RGB image after the correction is displayed on the RGB panel 35 as the RGB image signal after the color balance correction. Details of the color balance correction processing by the color balance controller 333 will also be described later with reference to the drawings.

Next, details of the tone conversion processing using the LUTs 3321, 3322, 3323, 3324, 3325, 3326, and 3421 by the RGB tone conversion circuit 332 and the LV tone conversion circuit 342, The details of the viewing angle correction processing by the hold circuits 343 and 344 and the color balance correction processing by the color balance controller 333 will be described in the following order.

&Lt; Details of the gradation conversion processing by the RGB gradation conversion circuit 332 and the LV gradation conversion circuit 342 &

In the related art, it has been described that a single LCD panel realizes linear gradation characteristics with respect to a human eye by performing gamma conversion on an input pixel value, but brightness in a dark region rises and black floating occurs.

In contrast to this, in the conventional method using the two LCD panels, an RGB image that is not subjected to gray level conversion is used for the RGB panel 35, a B / W image, it is possible to realize an improvement in contrast ratio and an improvement in black floating.

However, in this method, since the LV values are the same for each of R, G, and B sub-pixels constituting one pixel, there is a case where the color is whitened from pure color or the color balance is collapsed from the color mixture.

Therefore, in the first embodiment, in order to facilitate the color balance control at the subsequent stage, the RGB image obtained by performing the grayscale conversion using the RGB grayscale conversion circuit 332 is also used for the RGB panel 35 while the LV panel 36 is used. The gradation conversion is performed such that it can be used continuously in all the ranges so as not to be clipped to the upper limit in any range.

4 is a graph showing the gradation conversion characteristics of the LUT (R) 3321 in the first embodiment. Although the LUT (G) 3322 and the LUT (B) 3323 basically have the same gradation conversion characteristics as the LUT (R) 3321, the light transmission in each of the R, Because of the different efficiencies, the characteristics are slightly different from each other. 5 is a graph showing the gradation conversion characteristics of the LUT (W) 3421 in the first embodiment.

As a result of the experiment, it was found that the use of the gradation conversion characteristics as shown in Figs. 4 and 5 improves the color reproducibility of the black portion and the pure color of the dark portion and improves the problem of whitening from pure color.

The gradation conversion characteristic of the LUT (R) 3321 shown in Fig. 4 is realized, for example, by a gamma curve (Y = X ^? ) With? = 0.5. On the other hand, the tone conversion characteristics of the LUT (W) 3421 shown in FIG. 5 are obtained by measuring the transmitted light of the two LCD panels while changing the LV value with respect to the RGB values, and the input / output characteristics of the LV are determined so that? = 2.2.

<Details of the Viewing Angle Correction Process by the Horizontal and Vertical Edge Holding Circuits 343 and 344>

The horizontal direction edge hold circuit 343 performs local enlargement processing of the edge area of the image. There is no problem when the front of the two LCD panels is viewed. However, when viewed diagonally from the horizontal direction, the display image positions on the front side and the rear side are shifted in accordance with the angles due to the panel thickness so that problems such as double image and color misregistration . In order to solve this problem, the horizontal direction edge hold circuit 343 serves to correct the viewing angle in the horizontal direction with respect to the LV image.

6 is a detailed configuration diagram of the horizontal direction edge hold circuit 343 of the first embodiment. 7 is a flowchart related to the local edge hold process by the horizontal edge hold circuit 343 of the first embodiment.

6 and 7 show the local edge-hold processing of the horizontal 5-tap. The luminance values of the pixels of the LV image input in the horizontal line direction after gradation conversion are sequentially stored in the registers X1 to X5.

When it is detected that the luminance value of the center X3 pixel is the rising edge, that is, the luminance value of the X3 pixel is larger than the luminance value of the left pixel of X3, the horizontal direction edge hold circuit 343 sets the The luminance value is replaced with the luminance value of the X3 pixel. When it is detected that the luminance value of the center X3 pixel is the polling edge, that is, the luminance value of the X3 pixel is larger than the luminance value of the right pixel of X3, the horizontal direction edge hold circuit 343 outputs The luminance value is replaced with the luminance value of the X3 pixel.

The processing is limited to the case where X3 is equal to or greater than the threshold value 3 and the edge size ((X3-X2) or (X3-X4)) is equal to or greater than the threshold value 4. That is, the horizontal direction edge hold circuit 343 performs the local edge hold processing when the luminance difference is equal to or greater than a certain degree.

The register Y1 to Y5 and the selection 1 to the selection 5 shown in the lower part of Fig. 6 perform the above-described replacement operation. When the pixel replaced in the previous operation period is smaller than X3, .

The above-described replacement control signal is S1 to S5 in FIG. 6, and the horizontal edge hold circuit 343 does not perform the substitution when the control signal is 0, but performs the substitution when the control signal is 1.

Fig. 8 is a diagram showing waveforms of operation results of the local edge hold processing by the horizontal edge hold circuit 343 of the first embodiment. Fig. 8A shows an input waveform for the horizontal direction hold circuit 343, and Fig. 8B shows an output waveform for the input waveform in Fig. 8A. Each white circle in Fig. 8 corresponds to each pixel luminance value of the output image from the LV gradation conversion circuit 342. Fig. On the other hand, the black circle in Fig. 8 (b) corresponds to the luminance value of the edge-held pixel.

As shown in Fig. 8, by performing the local edge hold processing, it can be seen that the previous or next pixel is replaced with the value of the edge pixel. By performing the correction for improving the brightness of the adjacent pixels as described above, it is possible to prevent the image from becoming dark when viewed from the diagonal line in the horizontal direction.

The horizontal direction edge hold circuit 344 performs the viewing angle correction in the vertical direction with respect to the LV image. The vertical direction edge hold circuit 344 can be realized by the same configuration as that described above with respect to the horizontal direction edge hold circuit 343. [

&Lt; Detail of color balance correction processing by color balance controller 333 >

In this circuit, in the RGB gradation conversion circuit 332, a converted RGB image (first gradation-converted) subjected to the gradation conversion (first gradation conversion) by using the LUT (R) 3321, the LUT (G) 3322, and the LUT The color balance is adjusted using a correction coefficient for each pixel.

As shown in Fig. 2, the color balance controller 333 receives the following three signals.

The first input signals R, G, and B-bit expanded signals R1, G1, and B1 are input to the LUT (R) 3321, the LUT (G) 3322, the LUT G2, and B2, which are subjected to gradation conversion (first gradation conversion) by the first gradation conversion RGB signal (B) 3323,

Second input signal: The signal (R1, G1, B1) is subjected to the gradation conversion (second gradation conversion) by the three LUTs (W) 3324, 3325 and 3326 in the RGB gradation conversion circuit 332, The grayscale conversion RGB signals (L _R , L _G , L _B )

The third input signal: LV controller 34 in, through the tone converter (third grayscale conversion) by the LUT (W) (3421) generated, a third gray-level conversion signal _(W L)

The color balance controller 333 divides each of the second gradation-converted RGB signals (L _R , L _G , and L _B ) by the third gradation conversion signal (L _W ) as shown in the following equations (1) RGB signals R3 ', G3', and B3 'are generated by calculating the luminance ratios and multiplying the first tone conversion converted RGB signals R2, G2, and B2 by the luminance ratio.

R3 '= R2 (L _R / L _W ) (1)

G? 3 = _G ? 2 (L _G / L _W ) (2)

B 3 '= _{B 2} (L _B / L _W ) (3)

By displaying the RGB signals (R3 ', G3', B3 ') on the RGB panel 35, it is possible to solve the first and second problems described above. However, the color balance controller 333 outputs the RGB signals R3, R5, and R6 generated according to the following Expressions (4) to (6), which actually perform further adjustment on the RGB signals R3 ', G3' G3, and B3 are output to the rear RGB panel 35 as RGB image signals after color balance correction. Here, first and second problem solving will be described first.

&Lt; Explanation of the cause and solution of the first problem &

9 is an explanatory diagram for improving the color reproducibility of the dark portion by the operation of the RGB gradation conversion circuit 332 and the color balance controller 333 in the first embodiment. That is, the principle of the cause and solution of the first problem.

A method of improving the color reproducibility of the dark region will be described by taking, as an example, a case where a pixel expressing dark red color is displayed such that the value of R is 16 and the value of G and B is 0 as shown in Fig. 9 (a) . It is necessary to set the luminance value of the corresponding pixel of the LV panel 36 to, for example, 218 in the conventional method of improving the contrast ratio only with the LV image value.

In this case, since the luminance value of the LV panel 36 is set such that the R having the highest luminance among the sub-pixels is suitably displayed, as shown in Fig. 9 (a), the luminance of R after synthesized transmission becomes a desired value do. However, the intensities of G and B, which should be originally zero, are such that the amount of light passing through the LV panel 36 from the backlight is large and G and B emit light due to the G and B light spots in the RGB panel 35, (Gray) red color.

On the other hand, for example, as shown in Fig. 9 (b), the luminance value of R is set to a value larger than the original value (for example, 218), the LV image value is set to a small value of 16, The R after synthesized transmission exhibits the desired luminance, and G and B can be made so that the light scattering becomes very small, so that the red color is not grayish but pure greenish red.

3322, 3323, 3324, 3325, and 3326 in the RGB gradation conversion circuit 332 in the LUT (R) 3321, the LUT (G) 3322, and the LUT (B) 3323 in the LV gradation conversion circuit 342 is set to be raised upward from the linear characteristic, particularly in the dark area, and the LUT for LV (W) 3421 in the LV gradation conversion circuit 342 is lowered Is equivalent to the gradation conversion characteristics shown in Figs. 4 and 5 above.

&Lt; Cause of second problem and explanation of solution method >

FIG. 10 is an explanatory view of color balance adjustment in the dark area by the operation of the color balance controller 333 of the first embodiment. That is, the principle of the cause and solution of the second problem.

As an example, a case where a pixel representing a mixed color (R> G> B) other than RGB is displayed as shown in FIG. 10 (a) will be described as an example. As described above, the gray converter 341 generates the gray image for the RGB image to be represented by the maximum value of the RGB sub-pixel luminance value of each pixel. Thus, an LV image obtained by performing tone conversion on the luminance value equal to R, which is the subpixel whose luminance value is the maximum value, by the LUT (W) 3421 for LV is generated.

The LUT (R) 3321, the LUT (G) 3322, and the LUT (B) 3323 in the RGB gradation conversion circuit 332 perform LV gradation conversion The LUT (W) 3421 in the circuit 342 performs tone conversion so as to lower the LV luminance value. FIG. 10 (b) shows the result of such tone conversion with respect to FIG. 10 (a). However, even if such gradation conversion is performed, R after synthesized transmission obtains a desired luminance, but since G and B have a large luminance, the color balance is collapsed.

The second gradation-converted RGB signals L _R , L _G and L _B correspond to the three LUTs (W) 3324, 3325 and 3326 in the RGB gradation conversion circuit 332, To-gray conversion. In other words, the second gradation-converted RGB signals (L _R , L _G , and L _B ) are pixel values to be displayed in the corresponding pixels of the LV image in order to obtain the original RGB luminance. This is shown in Fig. 10 (c). In other words, in order to obtain the original luminance of G and B, it is necessary to change the luminance value in the LV image for each color of RGB as shown in Fig. 10 (c). However, since one pixel of the LV panel is the sum of the three subpixels of the RGB panel, each pixel of the LV image can not be changed for each of the RGB colors. Therefore, it is necessary to perform the RGB panel side tone adjustment in order to obtain the desired synthetic transmittance in all colors.

Therefore, as shown in Fig. 10 (d), it is possible to adjust the RGB panel side tone so that the combined transmittances of the RGB panel and the LV panel before and after the adjustment become equal to derive the adjusted brightness values R3, G3 and B3 do. To this end, L _R / L _W , L _G / L _W , and L _B / L _W are multiplied by the luminance ratio as shown in FIG. 10 (e) for each of the first tone conversion converted RGB signals R 2, _G 2 _{and B 2} , That is, R3 ', G3' and B3 'can be derived from the above-mentioned equations (1) to (3). As a result, when R3 ', G3' and B3 'are displayed on the RGB panel 35 as shown in FIG. 10 (f), W (= L _W ) is displayed on the LV panel 36, It becomes possible.

FIG. 2 and FIG. 9 show a specific configuration in which the color balance control method based on this principle is implemented. The original color can also be displayed in the color mixture portion, and the color reproducibility can be improved. Needless to say, this effect is exhibited not only in a dark area but also in a bright area.

<Derivation of RGB image signal after color balance correction>

As described above, in the first embodiment, not the RGB signals R3 ', G3' and B3 'obtained by the equations (1) to (3) but the RGB signals R3, G3 and B3, To the rear RGB panel 35 as an RGB image signal after color balance correction. This is difficult for the following reasons.

In the above-described configuration, the viewing angle correction is performed by the horizontal and vertical edge hold circuits 343 and 344 as described above, and the bright displayed area is widened by extending the edge, which is a portion with a large luminance difference, in the dark direction. In this widened edge part, a third gray-level conversion signal (L _W) is bright, and is adjusted, the color balance is corrected by it to the ground by the color balance controller (333) RGB signals (R3 ', G3', B3 ') is Respectively. That is, since the RGB signals R3 ', G3', and B3 'are adjusted to darken except for the subpixel with the maximum luminance value, the RGB image represented by the RGB signals R3', G3 ', and B3' And is corrected to be partially darkened.

In the case where a human is viewed from the front, the RGB signal (R3 ', G3', B3 ') and the third gradation conversion signal (L _W ) are outputted by the RGB panel 35 and the LV panel 36 , The light passing through these panels 35 and 36 is adjusted as described with reference to Fig. 10, so that an image with good color reproducibility is obtained. However, when viewed from a diagonal line, the RGB signals R3 ', G3', and B3 'are corrected so as to be partially darkened, so that the area to be brightly displayed is partially darkened. Side effects may occur.

In order to alleviate this side effect, in the first embodiment, a function F (RGB individual correction coefficient) in which the multiplication effect of the luminance ratio is reduced is determined in advance instead of the above equations (1) to (3) RGB image signals R3, G3, and B after the color balance correction, which are output to the rear-stage RGB panel 35 as shown in the following equations (4) to (6) B3).

_{R3 = R2 × F (L R} , L W) (4)

_{G3 = G2 × F (L G} , L W) (5)

B3 = B2 x F (L _B , L _W ) (6)

In the first embodiment, the RGB individual correction coefficient, that is, the function F is obtained by multiplying the luminance ratio by the adjustment function (1-TH) obtained by subtracting the predetermined value TH from 1 as shown in the following formulas (7) Value TH is further added.

F (L _R , L _W ) = (L _R / L _W ) (1 - TH) + TH (7)

F (L _G , L _W ) = (L _G / L _W ) (1 - TH) + TH (8)

F (L _B , L _W ) = (L _B / L _W ) (1 - TH) + TH (9)

11 is a graph showing a function F when the input is the luminance ratio in the equations (7) to (9). As shown in FIG. 11, the function F (61) has a luminance ratio (R) multiplied with respect to the first tone conversion converted RGB signals (R2, G2, B2) in equations (1) L _R / L _W , L _G / L _W , and L _B / L _W ) is equal to or less than a predetermined value TH. Here, when TH is 0, the clipping is not performed on the luminance ratio and the luminance ratio per se is used as the function F. The above equations (1) to (3) (R3, G3, B3).

The TH value is preferably 0.5 or more and 0.75 or less. The human eye tends to be more sensitive at a medium brightness than a bright luminance and a dark luminance. By setting the TH value as described above, it becomes possible to display an image so as to suppress side effects such as double lines, especially with respect to the luminance that the human eye senses sensitively.

As described above, in the first embodiment, the color balance controller 333 converts each of the color balance correction image signals (L _R , L _G , L _B ) after the second gradation conversion generated individually for RGB into a gray image signal (L _W) to divide the obtained brightness ratio _{(L R / L W, L} G / L W, L B / L W) in respect, station is an adjustment from 0 to 1, the function (1-TH) a further multiplied by RGB The individual correction coefficients F are calculated and the RGB image signals R3, G3, and B3 after the color balance correction are generated by multiplying the RGB image signals R2, G2, and B2 after the first tone conversion by the RGB individual correction factors F have. By suppressing the change range of the luminance ratio from the above equations (1) to (3) in this way, the luminance ratio is prevented from acting excessively, thereby effectively suppressing side effects such as double line while improving color reproducibility.

The function F can be realized by a circuit having a relatively simple structure.

The image display apparatus composed of two LCD panels of the first embodiment, which summarizes the above description, has technical features in the following circuit configuration and operation.

 The input RGB image is bit expanded by the bit expansion circuit 32 and then supplied to the RGB controller 33 and the LV controller 34.

 The LV controller 34 generates one gray image from the RGB maximum value for each pixel from the RGB image after the bit expansion, and performs a gray-scale transformation by the edge-hold processing after the gray-scale transformation using the LUT (W) 3421 for LV An LV image subjected to the viewing angle correction processing is generated and displayed on the LV panel.

 The RGB controller 33 performs the color balance correction after referring to the data of the LV image after performing the tone conversion using the LUT for RGB, thereby generating the RGB image and displaying it on the RGB panel.

 The color balance controller 333 calculates the RGB individual correction coefficient F by multiplying the luminance ratio by the adjustment function with the range from 0 to 1 and generates the RGB image signal after the color balance correction using the correction coefficient F .

As a result, it is possible to effectively suppress side effects such as double line, while realizing improvement in contrast ratio, improvement in black expression ability, and improvement in color reproducibility in dark areas.

Next, an image display method using the image display apparatus described as the first embodiment will be described with reference to Figs. 1 to 11. Fig.

The present image display method is constituted by superposing two front LCD panels and a rear LCD panel, and is executed by an image display device that performs image display by transmitting backlight in the order of the rear side LCD panel and the front side LCD panel An RGB image signal after color balance correction is generated by performing RGB gradation conversion processing and a color balance correction processing on an RGB image signal based on an input RGB image signal, A gray image signal after signal processing is generated by performing signal processing on the RGB image signal to supply RGB image signals after color balance correction to the front side LCD panel and gray image signals after signal processing to the rear side LCD panel In the RGB gradation conversion processing, the RGB image gradation conversion processing, which is stored separately for each color of RGB, And a second lookup table for performing a second tone conversion on the RGB image signal, the first lookup table for performing the first tone conversion on the input RGB image signal, A second lookup table is applied to the RGB image signal based on the input RGB image signal to perform the second tone conversion by performing the first tone conversion by applying the lookup table and generating the RGB image signal after the first tone conversion And the color balance correction processing generates each of the color balance correction image signals after the second gradation conversion generated individually for each RGB by the gray image signals after the signal processing, The RGB individual correction coefficient is calculated by further multiplying the adjustment function with the range from 0 to 1 for the ratio, For the RGB image signal after conversion crude RGB is multiplied by the individual correction factors.

First, the bit expanding circuit 32 performs bit extension processing on the input RGB image signal to generate an RGB image signal after bit expansion. The RGB image signal after the generated bit expansion is transmitted to the RGB controller 33 and the LV controller 34 as an RGB image signal based on the input RGB image signal.

The RGB controller 33 receives the RGB image signals after the bit expansion and performs the RGB gradation conversion processing on the RGB image signals after the bit expansion. More specifically, after the delay circuit 331 appropriately delays, the RGB gradation conversion circuit 332 has the first and second LUTs 3321, 3322, 3323, 3324, 3325, and 3326 for each color after the delay, RGB signals (R2, G2, B2) after the first gradation conversion and RGB signals (L _R , L _G , L _B ) after the second gradation conversion are generated by performing conversion (first and second gradation conversion). The generated signals are transmitted to the color balance controller 333.

The LV controller 34 receives the RGB image signal after bit expansion and performs signal processing on the RGB image signal after bit expansion to adjust the amount of transmission of the backlight. More specifically, first, the gray converter 341 converts the RGB image after the bit expansion into a gray image in which the maximum value among the three RGB values for each pixel is the representative value. Next, the LV gradation conversion circuit 342 performs gradation conversion (third gradation conversion) using the third LUT 3421 for the gray image. Further, the horizontal direction edge hold circuit 343 and the vertical direction hold circuit 344 apply the LPF 345 after performing the viewing angle correction on the gray image after the gray level conversion. The thus-generated third gradation conversion signal L _W , that is, the gray image signal L _W after signal processing is supplied to the LV panel (rear side LCD panel) 36 via the round processing section 346, And is transmitted to the color balance controller 333.

The color balance controller 333 performs color balance correction processing on the RGB signals (R2, G2, B2) after the first gradation conversion using the gray image signal (L _W ) after the signal processing, Thereby generating image signals R3, G3, and B3. The color balance correction is performed as described above with reference to Figs. 9 to 11. That is, the color balance correcting process is a process in which each of the color balance correcting image signals (L _R , L _G and L _B ) after the second gradation conversion generated individually for RGB is divided by the gray image signal (L _W ) (1-TH) having a range from 0 to 1 are further multiplied by the correction coefficients F (L _R / L _W , L _G / L _W and L _B / L _W ) Is performed by multiplying RGB image signals (R2, G2, B2) after gradation conversion by RGB individual correction factors F. RGB image signals (R3, G3, B3) after color balance correction are supplied to the RGB panel (front side LCD panel) 35 and displayed on the RGB panel 35.

Corrected RGB image displayed on the RGB panel 35 generated by adjusting the third tone conversion signal LW displayed on the LV panel 36 based on the signals R3 ', G3', and B3 ' Since the signals R3, G3, and B3 are basically the same as those described with reference to FIG. 10 (f), each RGB subpixel is displayed with an appropriate luminance value.

The image display method uses the image display device described as the first embodiment, needless to say, the same effect as that described in the image display device described as the first embodiment is obtained.

Next, the specific improvement effect on the suppression of the change range of the luminance ratio, that is, the color balance correction using the equations (4) to (6) will be described. Fig. 12 is a photograph of a result obtained by simulating a display in which a bright vertical line of a 10-pixel width on a dark background is displayed on an image display device having the configuration shown in Fig. 2, when viewed from a horizontal diagonal line. 12 (a) shows the RGB signals R3 ', G3' and B3 'calculated by the equations (1) to (3) in the color balance controller 333 for the LV panel 36, . 12B shows the RGB image signals R3, G3, and B3 after color balance correction calculated by the color balance controller 333 by the equations (4) to (6) for the LV panel 36 Transmitted and displayed.

In Fig. 12 (a), a white area is displayed on the left side of the vertical line with a dark area sandwiched therebetween, and a double line is shown. In Fig. 12 (b), the double line becomes thinner than that in Fig. 12 (a), that is, the color balance controller 333 multiplies the luminance ratio by the adjustment function with the range from 0 to 1 to alleviate side effects such as double line have.

13 is a photograph showing the result of displaying an image of a bright grid on a dark background on an actual machine. 13 (a) shows the RGB signals R3 ', G3', and B3 'calculated by the equations (1) to (3) in the color balance controller 333 for the LV panel 36, And Fig. 13 (b) is a photograph taken when viewed from the diagonal line. 13C and 13E show the RGB image signals R3, G3, and G4 after the color balance correction, which are calculated by the color balance controller 333 by the equations (4) to (6) B3 in Fig. 13, and the display is from the front, and Figs. 13 (d) and 13 (f) are photographs taken from the diagonal. In Figs. 13 (c) and 13 (d), TH of the equations (7) to (9) is 0.5, that is, the luminance ratio effect is suppressed to 50% as compared with the case of Figs. 13 (a) and 13 (b). 13 (e) and 13 (f), TH is 0.75, that is, the effect of the luminance ratio is suppressed to 25% as compared with the case of Figs. 13 (a) and 13 (b).

In Fig. 13 (b), a white area is displayed on the left side of the vertical line with a dark area sandwiched therebetween, and a double line is shown. In Fig. 13 (d), this double line becomes thinner than that in Fig. 13 (b), that is, the color balance controller 333 reduces the side effects such as double lines by multiplying the luminance ratio by the adjustment function with the range from 0 to 1 have. In Fig. 13 (f), the double line becomes thinner.

14 is a schematic sectional view of a display module using two LCD panels according to the first embodiment. The display module shown in Fig. 14 includes a lamination 38 for joining the RGB panel 35, the LV panel 36, the backlight unit 37, and the RGB panel 35 to the LV panel 36 .

The RGB panel 35 includes a color filter substrate 35b, a TFT substrate 35c, a polarizing film 35a, and a driving IC 35d. The color filter substrate 35b is a substrate on which a black matrix, R, G, and B color filters are arranged, and a common electrode or the like is formed. The TFT substrate 35c is a substrate on which TFTs, electrodes, and the like are formed on the liquid crystal side.

The polarizing film 35a polarizes the light emitted from the backlight unit 37. The driving IC 35d displays the RGB image processed by the RGB controller 33 on the RGB panel 35 by driving the TFT substrate 35c.

On the other hand, the LV panel 36 includes a glass substrate 36a, a TFT substrate 36b, a polarizing film 36c, and a driving IC 36d. The glass substrate 36a corresponds to the color filter substrate 35b of the RGB panel 35, but unlike the color filter substrate 35b, it does not have a black matrix and a color filter. This is based on the LV panel 36 displaying an LV image, i.e., a gray scale image expressed only with light and shade from white to black.

The TFT substrate 36b and the polarizing film 36c are the same as the TFT substrate 35c and the polarizing film 35a of the RGB panel 35. [ The driving IC 36d displays the LV image processed by the LV controller 34 on the LV panel 36 by driving the TFT substrate 36b.

When viewed from the front, the RGB panel 35 and the LV panel 36 are overlapped with each other so that corresponding pixels are superimposed and displayed.

The backlight unit 37 includes a light guide panel 37a and a light source 37b. The light source 37b irradiates the light to the light guide panel 37a. The light guide panel 37a refracts the light irradiated from the light source 37b and irradiates the LV panel 36 with the light. The light emitted from the light guide panel 37a passes through the overlapped LV panel 36 and the RGB panel 35 in order to reach the human eye viewing the image display apparatus.

The contrast ratio of each of the RGB panel 35 and the LV panel 36 is 1,500: 1, which is the same as that of the conventional one LCD panel. However, by adopting the two LCD panel structures as shown in Fig. 14, the contrast ratio is improved to 2,250,000: 1.

Furthermore, in Embodiment 1, the RGB controller 33 and the LV controller 34 perform tone conversion and color balance control in cooperation with each other to improve the gradation characteristics of the black region, thereby eliminating the so-called black floating phenomenon of the LCD panel, It is possible to realize a clear black display and to improve the color reproducibility at a low luminance (dark portion).

As described above, according to the first embodiment, there is shown a configuration capable of generating an RGB image in which the color balance is corrected in consideration of the gray level conversion result of the LV image while performing the gray level conversion for the RGB image. As a result, the following remarkable effects can be realized.

Effect 1: The contrast ratio can be improved and the black display capability can be improved as compared with the conventional image display device using an LCD panel.

Effect 2: Linearity and color reproducibility can be improved at low brightness (dark area).

Effect 3: It can be realized with a simple circuit configuration, and since the added circuit scale is small, there is a high cost-effective effect.

Effect 4: By suppressing the change range of the luminance ratio by the adjustment function, the luminance ratio is prevented from acting excessively, whereby the side effect such as double line is effectively suppressed while obtaining the above effect.

<Modifications>

Next, a modification of the image display apparatus shown as Embodiment 1 will be described. The present variation is different from the image display device shown as the first embodiment in the RGB individual correction coefficient of the color balance controller 333 shown in Fig. 2, that is, the function F is different.

In this modification, the RGB individual correction coefficient, that is, the function F is expressed as follows using the adjustment function M (L _W ).

F (L _R , L _W ) = (L _R / L _W ) × M (L _W ) (10)

F (L _G , L _W ) = (L _G / L _W ) × M (L _W ) (11)

F (L _B , L _W ) = (L _B / L _W ) × M (L _W ) (12)

FIG. 15 is a graph showing the adjustment function M (L _W ) in this modification. The adjustment function M (L _W ) is an input in which the gray image signal (L _W ) after signal processing is input, and the output value changes depending on the input value. The range of the adjustment function M (L _W ) ranges from 0 to 1, and more specifically, to a predetermined value k or more to 0.5 or less.

As can be seen from FIG. 15, the adjustment function M (L _W ) gradually decreases as the input value increases from 0, and gradually increases as the input value approaches the maximum value. Simulations and experiments with an actual machine have revealed that side effects such as double lines as described in the first embodiment tend to be conspicuous when the value of the gray image signal L _W after signal processing is intermediate. The adjustment function M (L _W ) takes this characteristic into account, and in particular, when the value of the gray image signal (L _W ) after signal processing is medium, the luminance ratio is not excessively applied.

The adjustment function M (L _W ) shown in Fig. 15 is set such that when the input value is represented by 8 bits, monotone decreases when the input value is equal to or greater than 0 and equal to or less than 64, and monotonously increases when equal to or greater than 194 and equal to or less than 255. The adjustment function M (L _W ) may be implemented as an LUT on a circuit.

Needless to say, the image display apparatus having the function F shown as the modification example has the same effect as the image display apparatus shown in the first embodiment.

Particularly, in the image display apparatus having the function F shown as the present variation, the luminance ratio is not excessively applied to the range of the value of the gray image signal (L _W ) after the signal processing in which a side effect such as double line is remarkable And the other range is set so that the luminance ratio effect can be sufficiently obtained. Therefore, it is possible to improve the color reproducibility better than the first embodiment while effectively suppressing side effects such as double lines.

The image display apparatus and the image display method of the present invention are not limited to the above-described embodiments and modifications described with reference to the drawings, but various modifications may be made in the technical scope thereof.

For example, the adjustment function M (L _W ) in the above modification may have a shape different from the shape shown in Fig. If the type of image to be displayed is limited and if any common feature is provided as a property, the property may be reflected in the adjustment function M (L _W ), for example, even when the input value is high, monotone increase may not occur.

Further, the adjustment function M (L _W ) of the modification example is set such that when the input value is represented by 8 bits, monotone reduction is performed when the input value is equal to or greater than 64 and less than 64, and monotonous increases when the input value is equal to or greater than 194 and 255, The threshold value may be a different value.

In addition, unless the scope of the present invention is not depart from the spirit and scope of the present invention, it is possible to select the configuration exemplified in the above-described embodiments and modifications, or appropriately change them to other configurations.

10: Image display device 20: Image display device main body
21: image processing engine 30: LCD module
31: I / F 32: Bit expansion circuit
33: RGB controller (first controller) 331: delay circuit
332: RGB gradation conversion circuit 333: color balance controller
34: LV controller (second controller) 341: Gray converter
342: LV gradation conversion circuit 343: horizontal edge hold circuit
344: vertical direction edge hold circuit 345: LPF
346: round processing section 35: RGB panel (front side LCD panel)
35b: color filter substrate 35c: TFT substrate
35a: polarizing film 36: LV panel (rear side LCD panel)
36a: glass substrate 36b: TFT substrate
36c: polarizing film 37: backlight unit
37a: light guide panel 37b: light source
38: lamination 3321, 3322, 3323: first lookup table
3324, 3325, 3326: Second lookup table
3421: Third lookup table

Claims (10)

Side LCD panel and a rear-side LCD panel, and the backlight is transmitted in the order of the rear-side LCD panel and the front-side LCD panel in order,
An RGB image signal after color balance correction is generated from an RGB image signal based on an input RGB image signal and an RGB image signal after the color balance correction is applied to the front side LCD panel, And a controller
A second controller for generating a gray image signal after the signal processing by performing signal processing on the RGB image signal based on the input RGB image signal and supplying the gray image signal after the signal processing to the rear side LCD panel Respectively,
The RGB gradation conversion circuit may include a first lookup table for performing a first gradation conversion on an RGB image signal and a second lookup table for performing a second gradation conversion on the RGB image signal, And the first look-up table is applied to the RGB image signal based on the input RGB image signal to generate the RGB image signal after the first gradation conversion, The second look-up table is applied to the RGB image signal based on the second look-up table to generate the color balance correction image signal after the second tone conversion,
The color balance controller may further include an adjustment function with a range of 0 to 1 with respect to a luminance ratio obtained by dividing each of the color balance correction image signals after the second gradation conversion generated for each RGB by the gray image signals after the signal processing And the RGB image signal after the first tone conversion is multiplied by the RGB individual correction coefficient to generate the RGB image signal after the color balance correction,
Wherein the RGB individual correction coefficient is calculated by multiplying the adjustment function obtained by subtracting a predetermined value from 1 with respect to the luminance ratio and further adding the predetermined value.
delete The method according to claim 1,
Wherein the predetermined value is not less than 0.5 and not more than 0.75.
delete Side LCD panel and a rear-side LCD panel, and the backlight is transmitted in the order of the rear-side LCD panel and the front-side LCD panel in order,
An RGB image signal after color balance correction is generated from an RGB image signal based on an input RGB image signal and an RGB image signal after the color balance correction is applied to the front side LCD panel, And a controller
A second controller for generating a gray image signal after the signal processing by performing signal processing on the RGB image signal based on the input RGB image signal and supplying the gray image signal after the signal processing to the rear side LCD panel Respectively,
The RGB gradation conversion circuit may include a first lookup table for performing a first gradation conversion on an RGB image signal and a second lookup table for performing a second gradation conversion on the RGB image signal, And the first look-up table is applied to the RGB image signal based on the input RGB image signal to generate the RGB image signal after the first gradation conversion, The second look-up table is applied to the RGB image signal based on the second look-up table to generate the color balance correction image signal after the second tone conversion,
The color balance controller may further include an adjustment function with a range of 0 to 1 with respect to a luminance ratio obtained by dividing each of the color balance correction image signals after the second gradation conversion generated for each RGB by the gray image signals after the signal processing And the RGB image signal after the first tone conversion is multiplied by the RGB individual correction coefficient to generate the RGB image signal after the color balance correction,
Wherein the adjustment function changes the output value depending on the input value by taking the gray image signal after the signal processing as an input,
Wherein the adjustment function gradually decreases as the input value increases from zero, and gradually increases as the input value approaches the maximum value.
6. The method of claim 5,
Wherein when the input value is represented by 8 bits, the adjustment function is monotone decreasing when the input value is equal to or greater than 0 and equal to or less than 64, and monotonously increasing when equal to or greater than 194 inclusive.
An image display method implemented by an image display device configured by superimposing two front-side LCD panels and a rear-side LCD panel, and in which backlight is transmitted through the rear-side LCD panel and the front- As a result,
An RGB image signal after color balance correction is generated by performing RGB gradation conversion processing and color balance correction processing on RGB image signals based on input RGB image signals,
A gray image signal after signal processing is generated by performing signal processing on the RGB image signal based on the input RGB image signal,
An RGB image signal after the color balance correction is supplied to the front side LCD panel,
A gray image signal after the signal processing is supplied to the rear side LCD panel,
In the RGB gradation conversion processing, a first lookup table for performing a first gradation conversion on an RGB image signal, which is separately stored for each color of RGB, and a second lookup table for performing a second gradation conversion on the RGB image signal The first look-up table is applied to an RGB image signal based on the input RGB image signal by the look-up table to perform the first tone conversion to generate an RGB image signal after the first tone conversion, The second look-up table is applied to the RGB image signal based on the image signal to perform the second gradation conversion to generate the image signal for color balance correction after the second gradation conversion,
In the color balance correction processing, an adjustment function with a range of 0 to 1 is applied to the luminance ratio obtained by dividing each of the color balance correction image signals after the second gradation conversion generated individually for each RGB by the gray image signals after the signal processing And the RGB individual correction coefficients are multiplied by the RGB image signals after the first gradation conversion,
Wherein the RGB individual correction coefficient is calculated by multiplying the adjustment function obtained by subtracting a predetermined value from 1 with the luminance ratio and further adding the predetermined value.
8. The method of claim 7,
Wherein the predetermined value is 0.5 or more and 0.75 or less.
An image display method implemented by an image display device configured by superimposing two front-side LCD panels and a rear-side LCD panel, and in which backlight is transmitted through the rear-side LCD panel and the front- As a result,
An RGB image signal after color balance correction is generated by performing RGB gradation conversion processing and color balance correction processing on RGB image signals based on input RGB image signals,
A gray image signal after signal processing is generated by performing signal processing on the RGB image signal based on the input RGB image signal,
An RGB image signal after the color balance correction is supplied to the front side LCD panel,
A gray image signal after the signal processing is supplied to the rear side LCD panel,
In the RGB gradation conversion processing, a first lookup table for performing a first gradation conversion on an RGB image signal, which is separately stored for each color of RGB, and a second lookup table for performing a second gradation conversion on the RGB image signal The first look-up table is applied to an RGB image signal based on the input RGB image signal by the look-up table to perform the first tone conversion to generate an RGB image signal after the first tone conversion, The second look-up table is applied to the RGB image signal based on the image signal to perform the second gradation conversion to generate the image signal for color balance correction after the second gradation conversion,
In the color balance correction processing, an adjustment function with a range of 0 to 1 is applied to the luminance ratio obtained by dividing each of the color balance correction image signals after the second gradation conversion generated individually for each RGB by the gray image signals after the signal processing And the RGB individual correction coefficients are multiplied by the RGB image signals after the first gradation conversion,
Wherein the adjustment function changes the output value depending on the input value by taking the gray image signal after the signal processing as an input,
Wherein the adjustment function gradually decreases as the input value increases from zero and gradually increases as the input value approaches the maximum value.
10. The method of claim 9,
Wherein when the input value is represented by 8 bits, the adjustment function is monotone decreasing when the input value is equal to or greater than 0 and equal to or less than 64, and monotonously increasing when equal to or greater than 194 inclusive.

Images